Optical Generation of Hydrated Electrons from Aromatic Compounds

Grossweiner, Leonard I.; Joschek, Hans-Ingo

doi:10.1021/ba-1965-0050.ch020

Cited by 76 publications

(23 citation statements)

References 6 publications

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“…Single exponential decays were fit to a function of the form I(t) = A exp(-t/T)+B [1] in which I(t) is the calculated intensity at the time t, A is the amplitude, r is the fluorescence lifetime, and B is a baseline parameter. The nonexponential decays could be fit well by the sum of two exponentials, [2] in which T1 and T2 are the lifetimes of the two components and f is the weight of the component having lifetime Tr.…”

Section: Resultsmentioning

confidence: 99%

“…It has long been known (2) that irradiation of aqueous tryptophan and other indole derivatives in the 280-nm absorption band leads to the formation of solvated electrons. Although there is still some uncertainty about the yield (3), because of the presence of fast recombination of the ejected electron with the counter radical cation, this photoionization is generally thought to be monophotonic and a major nonradiative pathway (4).…”

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confidence: 99%

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Nonexponential fluorescence decay of aqueous tryptophan and two related peptides by picosecond spectroscopy

Fleming

Morris

Robbins

et al. 1978

Proc. Natl. Acad. Sci. U.S.A.

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Time-resolved fluorescence spectroscopy of tryptophan and two related dipeptides, tryptophylalanine and alanyltryptophan, has been carried out on the subnanosecond time scale by using picosecond exciting pulses at a wavelength of 264 nm. Detection was with an ultrafast streak camera coupled to an optical multichannel analyzer. The zwitterions of these molecules show a definite nonexponential fluorescence decay which can be analyzed in terms of two exponentials. The two decay rates increase strongly with increasing temperature, as does the weight of the faster component. In tryptophan at pH 11, where the amino group is deprotonated, there remains only a single temperature-dependent exponential. The results are interpreted in terms of two kinds of trapped conformers in the excited state that interconvert no quicker than the time scale of the fluorescence. A model is suggested in which the nonradiative processes in one conformer approximate those in the bare indole moiety. The nonradiative decay rate of the other conformer is substantially faster. It is believed that the process responsible for this fast decay is intramolecular electron transfer from the indole ring to the amino acid side chain. The predilection for this electron transfer depends on steric relationships as well as on the electron-attracting power of the carbonyl group. This picture is consistent with earlier fluorescence quantum yield results. In fact, a self-consistent picture emerges from the temporal and yield data that quantitatively explains most important facets of tryptophan photochemistry in aqueous solution.Tryptophan is the most photochemically labile of the amino acids and plays an important role in the photolysis and photoinactivation of proteins and enzymes (1). (cf. ref. 8; 9) lying in the range 2.6-3.0 nsec. At pH 10-11, the lifetime increases (9) to -9.0 nsec. However, these measurements were all made by the method of time-correlated singlephoton counting, assuming a single exponential for the functional form of the fluorescence decay curve. Recently it has been shown that the decay of tryptophan in neutral solution is not a simple exponential (10,11 The publication costs of this article were defrayed in part by page charge payment. This article must therefore be hereby marked "advertisement" in accordance with 18 U. S. C. §1734 solely to indicate this fact.Proc. Natl. Acad. Sci. USA 75 (1978) 4653 The experimental apparatus used for the fluorescence decay measurements is similar to that described in recent publications (12, 13). The fluorescence decay curves were obtained by excitation of the various solutions contained in a 1-cm-path-length quartz cuvette. A single pulse selected from the output of a mode-locked Nd3+:phosphate glass laser was amplified and then converted to the fourth harmonic by two frequencydoubling stages before being used for excitation (X -264 nm; tp 6 psec; E 0.2 mJ). Solutions were deoxygenated by bubbling with argon and were changed after each series of 15 laser shots to prevent the possible...

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Section: Resultsmentioning

confidence: 99%

mentioning

confidence: 99%

Nonexponential fluorescence decay of aqueous tryptophan and two related peptides by picosecond spectroscopy

Fleming

Morris

Robbins

et al. 1978

Proc. Natl. Acad. Sci. U.S.A.

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“…Lors de l'excitation de dérivés phénoliques, le processus primaire suivant l'excitation est connu comme faisant intervenir un mécanisme de photo éjection d'électrons à partir de l'état excité du phénol (JOSCHEK et GROSSWEINER, 1966). Un état intermédiaire où les trois espèces radicales phénoxyle-électron-proton sont potentiellement formées est généralement proposé.…”

Section: Influence De L'oxygène Dissous (λ = 254 Nm)unclassified

Cinétique de phototransformation de polluants organiques émergents en solution aqueuse diluée

Meite

Szabó

Mazellier

et al. 2010

rseau

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Les vitesses de phototransformation de quatre hormones (estradiol, éthinylestradiol, progestérone, testostérone) et de deux anti-inflammatoires non stéroïdiens (diclofénac et naproxen) ont été étudiées en milieu aqueux dilué. Les expériences de photolyse ont été réalisées sous irradiation monochromatique (254 nm) et sous irradiation polychromatique (λ > 280 nm). Les résultats expérimentaux ont montré que les rendements quantiques de photodécomposition sont faibles (entre 0,02 et 0,08) à l’exception du diclofénac (de l’ordre de 0,30). L’influence de la concentration en oxygène dissous sur les rendements quantiques de photolyse a aussi été examinée. À partir des résultats obtenus, les rendements d’élimination des composés étudiés dans les conditions de désinfection des eaux par irradiation UV à 254 nm ont été estimés.The photodecomposition of some emerging organic pollutants (4 hormones: estradiol, ethynylestradiol, progesterone, testosterone; and 2 nonsteroidal anti-inflammatory drugs: diclofenac and naproxen) has been investigated in dilute aqueous solution. The photolysis experiments were carried out under monochromatic irradiation (254 nm) and under polychromatic irradiation (λ > 280 nm). The calculated quantum yields of photodecomposition under monochromatic irradiations were low (between 0.02 and 0.08) except for diclofenac for which the value was about 0.30. The influence of oxygen concentration was also examined and the removal yields of these compounds under the conditions used for the UV-disinfection of drinking water at 254 nm were estimated

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“…(49,92) The most direct evidence for the existence of this mechanism is derived from flash photolysis studies, which have shown that ultraviolet irradiation of aqueous solutions of indole and its derivatives, including tryptophan, results in formation of solvated electrons. (93,94) While accurate measurements of the quantum yield of solvated electrons will be required to assess the quantitative significance of this mechanism, there is considerable indirect evidence that it may be an important factor in the radiationless deactivation of the indole excited state. The quantum yield of indole in water is strongly temperature dependent.…”

Section: Radiationless Deactivation Of the Excited Statementioning

confidence: 99%